High-Flux lamellar MoSe2 membranes for efficient dye/salt separation

Membrane-based technology is emerging as an efficient technique for wastewater treatment in recent years. Membranes made up of two-dimensional materials provide high selectivity and water flux compared to con-ventional polymeric membranes. Herein, we report the synthesis and use of MoSe2 membrane for dye and drug separation in wastewater, mainly from textile and pharmaceutical industries. The as-prepared MoSe2 membrane shows similar to 100% rejection for organic dyes and ciprofloxacin drug with a water flux reaching up to similar to 900 Lm(-2)h(-1)bar(-1). Further, the MoSe2 membrane shows lower NaCl rejection of similar to 1.9% for the dye/salt mixture. The interlayer spacing in the MoSe2 membrane allows the water molecules and ions from the salt to pass through freely but restricts the movement of large contaminants. The membrane is stable against the bovine albumin serum fouling with a flux recovery rate of 96%. It also shows good performance even in harsh environments (pH 3-10). To the best of our knowledge, the MoSe2 membranes were fabricated for the first time for wastewater treatment application. The dye/salt separation performance of the MoSe2 membrane is significantly better than several other membranes. This work highlights the promising potential for using two-dimensional materials for textile and pharmaceutical wastewater treatment.

Automated summary

Membrane-based technology, particularly membranes made up of two-dimensional materials such as MoSe2, is proving to be an efficient technique for wastewater treatment. The MoSe2 membrane shows high rejection rates for organic dyes and ciprofloxacin drug, along with a high water flux. It also exhibits good stability against fouling and performs well in harsh environments, making it a promising option for textile and pharmaceutical wastewater treatment.